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This page is written by Evgeniy Shkondin @DTU Nanolab if nothing else is stated.
All images and photos on this page belongs to DTU Nanolab.
The fabrication and characterization described below were conducted in 2021 by Evgeniy Shkondin, DTU Nanolab.

MgO Sputtering

This page presents the results of MgO deposition using RF sputtering in Sputter-System Lesker, now commonly known as "Old Lesker". The deposition target is MgO, and a small fraction of O₂ as reactive gas has been added to improve the stoichiometry. Source #5 (RF) was used.

The prepared samples were investigated by Spectroscopic Ellipsometry, X-ray photoelectron spectroscopy, and most importantly, the X-ray Reflectivity method. The focus of the study was the deposition conditions and the analysis of the refractive index.

The process recipe in a Sputter-System (Lesker) is following:

Deposition type: RF-R
Power: 60 W.
Pressure: 5 mTorr
Gas: 2% of O₂ in Ar
Deposition time: 14400s, 28800s, 43200s, and 57600s which corresponds to 4, 8, 12, and 16 hours.
Temperature: 20°C (no heating)
Measured DC bias: fluctuates 36-48V

The characterization reveals a complex structure of the deposited layers. The best way to describe the samples is to implement the following model (shown in a figure). The MgO film contains a bottom intermediate layer with constant and relatively high electron density. On top of it, there is a main layer of MgO, where the density is a linear function of the depth. The highest density is on the bottom and the lowest at the top. The topmost layer contains moisture, where MgO bounds carbon and water.

Appling this complexity allows fitting XRR data. Additionally, such structure is also supported by XPS analysis, where the chemical shifts of Mg-1s and O-1s support the idea.

The deposition rate derived from the XRR analysis illustrated in a figure is based on the thickness measurements which include the bottom intermediate layer, main layer, and moisture. This is the more reliable way of the procedure. Ellipsometry cannot take care of such complexity and ellipsometric measurement should only be used as a guide.

Figure 1. Deposition rate and ssample modeling.
Deposition rate measured by ellipsometry and X-ray Reflectivity analysis.
MgO sample model.

Characterization

X-Ray Reflectivity

X-ray reflectivity (XRR) profiles for MgO films at four different deposition times (4h, 8h, 12h, 16h) has been obtained using Rigaku XRD SmartLab equipment with standard 2 $\theta$ / $\omega$ scans. The voltage and current settings for the Cu X-ray tube were standard 40kV and 30mA. The incident optics contained a IPS (incident parallel slit) adaptor with 5 ° Soller slit. Other slits: IS=0.03mm RS1=0.03mm and RS2=0.075mm. Step size: 0.01 and measurement time - 5s for each point. Fitting procesure was performed using commercial GlobalFit software assuming the model based on Si substrate with native oxide followed by the deposited complex MgO film illustrated on a model figure. The results are summarized in a tables below.

Figure 2. XRR measurements and modelling.
4 hours.
8 hours.
12 hours.
16 hours.

4 hours deposition summary table

Layer parameter list
Layer name	Thickness (nm)	Density (g/cm³)	Rougness (nm)	Depth distribution	Bottom density (g/cm³)	Delta	Beta
Moisture	4.64	1.04	0.00	No distribution		3.3961e-6	7.8861e-8
MgO	5.12	2.57	1.25	Linear	4.83	8.2587e-6	8.5696e-8
MgO intermediate layer	2.75	2.79	3.05	No distribution		9.0818e-6	2.1089e-7
SiO₂ native oxide	1.81	1.40	0.58	No distribution		4.5656e-6	1.0602e-7
Si wafer	$\infty$	2.33	0.74	No distribution		7.5795e-6	1.7601e-7

8 hours deposition summary table

Layer parameter list
Layer name	Thickness (nm)	Density (g/cm³)	Rougness (nm)	Depth distribution	Bottom density (g/cm³)	Delta	Beta
Moisture	4.71	1.12	0.56	No distribution		3.6587e-6	8.4960e-8
MgO	13.54	2.64	1.55	Linear	4.42	8.4961e-6	8.8159e-8
MgO intermediate layer	1.93	3.26	2.52	No distribution		1.0606e-5	2.4629e-7
SiO₂ native oxide	2.07	1.83	0.40	No distribution		5.9538e-6	1.3826e-7
Si wafer	$\infty$	2.33	0.24	No distribution		7.5795e-6	1.7601e-7

12 hours deposition summary table

Layer parameter list
Layer name	Thickness (nm)	Density (g/cm³)	Rougness (nm)	Depth distribution	Bottom density (g/cm³)	Delta	Beta
Moisture	5.23	1.03	0.92	No distribution		3.3640e-6	7.8117e-8
MgO	18.03	2.44	1.85	Linear	3.77	7.8652e-6	8.1613e-8
MgO intermediate layer	5.54	3.58	0.15	No distribution		1.1652e-5	2.7058e-7
SiO₂ native oxide	2.39	2.22	0.21	No distribution		7.2460e-6	1.6826e-7
Si wafer	$\infty$	2.33	0.02	No distribution		7.5795e-6	1.7601e-7

16 hours deposition summary table

Layer parameter list
Layer name	Thickness (nm)	Density (g/cm³)	Rougness (nm)	Depth distribution	Bottom density (g/cm³)	Delta	Beta
Moisture	4.57	1.04	1.02	No distribution		3.3747e-6	7.8365e-8
MgO	30.01	2.66	2.07	Linear	3.84	8.5682e-6	8.8908e-8
MgO intermediate layer	4.99	3.62	0.63	No distribution		1.1785e-5	2.7366e-7
SiO₂ native oxide	2.18	2.12	0.44	No distribution		7.2018e-6	1.6724e-7
Si wafer	$\infty$	2.33	0.02	No distribution		7.5795e-6	1.7601e-7

X-ray Photoelectron Spectroscopy

XPS profiles for MgO films has been obtained using XPS K-Alpha equipment. Here only 12h deposition sample is shown, but all samples look similar. Depth profiles have been acquired using monoatomic Ar+ bombardment. The etching time is 10s. 3000 eV energy ang high current settings are used.

Figure 3. XPS analysis.
MgO XPS Survey.
MgO sample model.

Depth-profiles

Depth profiles show chemical shifts of O-1s and Mg-1s peaks as a function of etch depth. The shape prooves the model given on the model image figure where MgO thin film contains bottom intermediate layer, main Layer with the linearly dependent density, and the topmost layer of moisture. This model is also successfully applied for XRR fitting.

Figure 4. Depth-profile XPS analysis.
Mg 1s. Surface and first two etch levels only.
O 1s. Surface and first two etch levels only.
Si 2p. Surface and first two etch levels only.
C 1s. Surface and first two etch levels only.
Mg 1s. Total depth.
O 1s. Total depth.
Si 2p. Total depth.
C 1s. Total depth.

Spectroscopic Ellipsometry

The spectroscopic ellipsometry measurements were conducted by using VASE Ellipsometer. The purpose of the investigation is to see how the change in thickness affects the shape of the refractive index. Other parameters - such as layer thickness were also extracted.

The Cauchy layer is a commonly used layer for determing the optical constants of transparent or semitransparent films (Dielectric or Semiconductors below the fundamental bandgap). Over part of the spectral range, the optical constants of these materials can be represented by an index that varies slowly as a function of the wavelength and the exponential absorption tail. The index of refraction of the Cauchy layer is represented by an inverse power series containing only even terms and the extinction coefficient is represented by a simple exponential tail.

$n(\lambda )=A+{\frac {B}{\lambda ^{2}}}+{\frac {C}{\lambda ^{4}}}$

$k(E)=k\cdot e^{exp(E-BandEdge)}$

There are three terms (A, B, and C) for the index of refraction (n), and there are three additional terms to describe an Urbach absorption tail. The k Amplitude and exp (Exponent coefficient) are fit parameters for determining the shape of the extinction coefficient dispersion. The BandEdge parameter can be set manually but is not a fit parameter since it is directly correlated to the k Amplitude parameter (the extinction coefficient is equal to k Amplitude at the band edge). Here, the BandEdge=400nm

Below there is a table that shows the ellipsometry fitting result, assuming the Cauchy dispersion.

Layer parameter list
Sample name	A	B	C	k	exp	Thickness	Roghness
4 hours	1.185	0.01476	-0.00012589	0.01666	0.903	19.70	3.89
8 hours	1.437	0.02146	-0.00032685	0.00286	0.764	25.39	3.85
12 hours	1.475	0.01990	-0.00031736	0.02060	0.207	35.52	3.82
16 hours	1.572	0.01553	-0.00021398	0.00479	0.833	42.04	2.96

Figure 5. Uniformity of deposited MgO layer accros 4-inch wafer.
12h deposition sample.

Optical functions

Figure 6. Modeling of the refractive index.
$Refractive index for the films with different thicknesses.$

Refractive index for the films with different thicknesses.

@@ Line 1: / Line 1: @@
 '''Feedback to this page''': '''[mailto:labadviser@nanolab.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.nanolab.dtu.dk/index.php/Specific_Process_Knowledge/Thin_film_deposition/Deposition_of_MgO click here]'''
+<i>This page is written by <b>Evgeniy Shkondin @DTU Nanolab</b> if nothing else is stated. <br>
+All images and photos on this page belongs to <b>DTU Nanolab</b>.<br>
+The fabrication and characterization described below were conducted in <b>2021 by Evgeniy Shkondin, DTU Nanolab</b>.<br></i>
 =MgO Sputtering=
@@ Line 5: / Line 10: @@
 This page presents the results of MgO deposition using <b>RF sputtering</b> in Sputter-System Lesker, now commonly known as "Old Lesker". The deposition target is <b>MgO</b>, and a small fraction of O<sub>2</sub> as reactive gas has been added to improve the stoichiometry. Source #5 (RF) was used.
-The fabrication and characterization described below were conducted in <b>2021 by Evgeniy Shkondin, DTU Nanolab</b>. The prepared samples were investigated by Spectroscopic Ellipsometry, X-ray photoelectron spectroscopy, and most importantly, the X-ray Reflectivity method. The focus of the study was the deposition conditions and the analysis of the refractive index.
+The prepared samples were investigated by Spectroscopic Ellipsometry, X-ray photoelectron spectroscopy, and most importantly, the X-ray Reflectivity method. The focus of the study was the deposition conditions and the analysis of the refractive index.